Reliable positioning method of intelligent vehicles based on factor graph in GNSS-denied environment

被引：0

作者：

Hu Y. ^{[1
]}

Li X. ^{[1
]}

Xu Q. ^{[1
]}

Yuan J. ^{[2
]}

Kong X. ^{[1
]}

机构：

[1] School of Instrument Science and Engineering, Southeast University, Nanjing

[2] Traffic Management Research Institute of the Ministry of Public Security, Wuxi

来源：

Yi Qi Yi Biao Xue Bao/Chinese Journal of Scientific Instrument | 2021年 / 42卷 / 11期

关键词：

Confidence interval; Error of non line of sight; Factor graph; GNSS-denied; Vehicle positioning;

D O I：

10.19650/j.cnki.cjsi.J2108296

中图分类号：

学科分类号：

摘要：

Aiming at the demand for accurate and reliable positioning of intelligent vehicles in GNSS-denied environments such as indoor parking lots and tunnels, a low-cost fusion positioning method based on factor graph is proposed. Firstly, a UWB/INS dynamic fusion positioning framework based on factor graph is established; secondly, through making full use of the static characteristics of the UWB base stations, the maximum theoretical distances between the base stations and the intelligent vehicle are calculated via the position and position confidence interval inferred from the factor graph, and compared with the distance measured by UWB to detect the non-line-of-sight signals; lastly, an adaptive fusion rule is formulated to guide the fusion of UWB/INS under different conditions, the final positioning result is obtained, and the reliable positioning of intelligent vehicles in GNSS-denied environments is achieved. The real vehicle tests show that the proposed fusion positioning method can achieve the positioning accuracy of 0.622 m, which is more than one time improvement compared with that of the traditional least square method. The proposed method effectively suppresses the influence of non-line-of-sight errors, has the advantages of low cost, high reliability, strong environment adaptability, and overcomes the shortcomings of traditional methods. © 2021, Science Press. All right reserved.

引用

页码：79 / 86

页数：7

共 18 条

[1] SHEN K, LIU T X, ZUO S Q, Et al., Observability analysis and robust fusion algorithms of GNSS/INS integrated navigation in complex urban environment, Chinese Journal of Scientific Instrument, 41, 9, pp. 254-263, (2020)
[2] SONG M M., Bag of words based approach for geomagnetic fingerprinting based indoor positioning, Journal of Electronic Measurement and Instrumentation, 33, 10, pp. 195-200, (2019)
[3] COMUNIELLO A, MOSCHITTA A, ANGELIS A D., Ultrasound TDoA positioning using the best linear unbiased estimator and efficient anchor placement, IEEE Transactions on Instrumentation and Measurement, 69, 5, pp. 2477-2486, (2020)
[4] ZHENG Z, LI X, SUN Z, Et al., A novel visual measurement framework for land vehicle positioning based on multi-module cascaded deep neural network[J], IEEE Transactions on Industrial Informatics, 17, 4, pp. 2347-2356, (2021)
[5] LYU P, XIN Y, ZHANG H, Et al., Tightly coupled localization of IMU and lidar based on MSCKF, Chinese Journal of Scientific Instrument, 41, 8, pp. 15-22, (2020)
[6] SUN Y J, WANG X M, YU J Y., Heuristic localization algorithm for low density of anchor nodes in wireless sensor networks, Chinese Journal of Scientific Instrument, 39, 1, pp. 225-233, (2018)
[7] SONG X, LI X, TANG W, Et al., A fusion strategy for reliable vehicle positioning utilizing RFID and in-vehicle sensors, Information Fusion, 31, pp. 76-86, (2016)
[8] WANG J, GAO Y, LI Z, Et al., A tightly-coupled GPS/INS/UWB cooperative positioning sensors system supported by V2I communication, Sensors, 16, 7, pp. 944-959, (2016)
[9] FAN Q, SUN B, SUN Y, Et al., Data fusion for indoor mobile robot positioning based on tightly coupled INS/UWB, Journal of Navigation, 70, 5, pp. 1079-1097, (2017)
[10] LI R B, WANG N Z, LIU J Y, Et al., UWB ranging error estimation and compensation method for relative navigation, Chinese Journal of Scientific Instrument, 40, 5, pp. 31-38, (2019)

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